Work and Simple Machines Objectives: 1) know how six different

Work and Simple
Machines
Objectives:
1) know how six different simple machines
are used in every day life to make work
easier
2) be able to calculate the mechanical
advantage, and efficiency of machines.
1
What are the 6 types of
Simple Machines
•
The six simple machines are:
–
–
–
–
–
–
Lever
Wheel and Axle
Pulley
Inclined Plane
Wedge
Screw
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What is a Simple Machines
• A machine is a device that helps make
work easier to perform by
accomplishing one or more of the
following functions:
– transferring a force from one place to
another,
– changing the direction of a force,
– increasing the magnitude of a force, or
– increasing the distance or speed of a
force.
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Mechanical Advantage
• It is useful to think about a machine in
terms of the input force (the force you
apply) and the output force (force
which is applied to the task).
• When a machine takes a small input
force and increases the magnitude of
the output force, a mechanical
advantage has been produced.
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No machine can increase
both the magnitude and the
distance of a force at the
same time.
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The Lever
• A lever is a rigid bar
that rotates around a
fixed point called the
fulcrum.
• The bar may be either
straight or curved.
• In use, a lever has both
an effort (or applied)
force and a load
(resistant force).
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The 3 Classes of Levers
• The class of a lever
is determined by the
location of the
effort force and the
load relative to the
fulcrum.
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First Class Lever
• In a first-class lever the fulcrum is
located at some point between the
effort and resistance forces.
– Common examples of first-class levers
include crowbars, scissors, pliers, tin
snips and seesaws.
– A first-class lever always changes the
direction of force (I.e. a downward effort
force on the lever results in an upward
movement of the resistance force).
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Fulcrum is between EF (effort) and RF (load)
Effort moves farther than Resistance.
Multiplies EF and changes its direction
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Second Class Lever
• With a second-class lever, the load is
located between the fulcrum and the effort
force.
• Common examples of second-class levers
include nut crackers, wheel barrows, doors,
and bottle openers.
• A second-class lever does not change the
direction of force. When the fulcrum is
located closer to the load than to the effort
force, an increase in force (mechanical
advantage) results.
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RF (load) is between fulcrum and EF
Effort moves farther than Resistance.
Multiplies EF, but does not change its direction
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Third Class Lever
• With a third-class lever, the effort
force is applied between the fulcrum
and the resistance force.
– Examples of third-class levers include
tweezers, hammers, and shovels.
– A third-class lever does not change the
direction of force; third-class levers
always produce a gain in speed and
distance and a corresponding decrease in
force.
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EF is between fulcrum and RF (load)
Does not multiply force
Resistance moves farther than Effort.
Multiplies the distance the effort force travels
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Wheel and Axle
• The wheel and axle is a
simple machine
consisting of a large
wheel rigidly secured
to a smaller wheel or
shaft, called an axle.
• When either the wheel
or axle turns, the other
part also turns. One full
revolution of either part
causes one full
revolution of the other
part.
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Fixed Pulley
A pulley is said to
be a fixed pulley if
it does not rise or
fall with the load
being moved. A
fixed pulley
changes the
direction of a
force; however, it
does not create a
mechanical
advantage.
Movable Pulley
• A moveable
pulley rises and
falls with the load
that is being
moved. A single
moveable pulley
creates a
mechanical
advantage.
Mechanical Advantage
of a Pulley
Inclined Plane
• An inclined plane is
an even sloping
surface. The
inclined plane
makes it easier to
move a weight from
a lower to higher
elevation.
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Inclined Plane
• The mechanical
advantage of an
inclined plane is
equal to the length
of the slope divided
by the height of the
inclined plane.
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Wedge
• The wedge is a
modification of the
inclined plane.
Wedges are used as
either separating or
holding devices.
• A wedge can either
be composed of one
or two inclined
planes. A double
wedge can be thought
of as two inclined
planes joined
together with their
sloping surfaces
outward.
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Screw
• The screw is also a
modified version of
the inclined plane.
• While this may be
somewhat difficult
to visualize, it may
help to think of the
threads of the
screw as a type of
circular ramp (or
inclined plane).
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MA of an screw can be calculated by dividing the number of turns
per inch.
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Efficiency
• We said that the input force times the distance equals the
output force times distance, or:
Input Force x Distance = Output Force x Distance
However, some output force is lost due to friction.
• The comparison of work input to work output is called
efficiency.
• No machine has 100 percent efficiency due to friction.
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